JP2000511717A - Method and apparatus for processing digital signals - Google Patents

Abstract

(57) Abstract The present invention relates to a method and apparatus for analyzing a digital video signal in preparation for digital compression coding of the digital video signal. The signal (20) is applied to the analyzer (22) to store the samples of the video signal and obtain a difference signal representing the number of parameters of the signal. One such parameter is the absolute difference between each pixel sample of vertically and temporally adjacent signals, that is, the absolute difference between each sample and the sample one frame period later. Other parameters of the video signal are derived from the absolute differences between pixel samples taken over a period of one line, one field and one sample interval. A control signal representing the coding threshold of the input video signal is obtained by accumulating the difference signals and combining them as a weighted sum. The bandwidth of the low-pass filter in the pre-processing unit (preprocessor) (21) is controlled by a control signal, filters the video signal (20), converts the compressed signal into a coded signal in the signal. -Eliminate or limit components that may cause artifacts. The control signal is also sent to other components in the transmission chain, such as an encoder (23) and a statistical multiplexer (24) to indicate early on image criticality.

Description

DETAILED DESCRIPTION OF THE INVENTION     Method and apparatus for processing digital signals   The present invention uses an input digital signal to generate a signal for digital compression. And a method for processing the same.   Digital video compression systems typically perform many preprocessing functions first. The video signal is adjusted in advance by these functions, and For the tartlet, a better image can be obtained than when no preprocessing is performed. You. Examples of such operations are horizontal and downward sampling and noise reduction techniques. You.   The quantization parameters generated by the compression encoder are used to encode encoded artifacts. Control parameter to control the amount of pre-processing applied to the input video signal to reduce It can be used as a parameter. However, to control preprocessing operations, If the quantization parameter (QP) is used from the coder, positive feedback (positive feedback) ) Occurs and the system becomes unstable.   In order to interrupt the feedback loop, the compression The incoming video signal itself must be analyzed before estimating the "criticality" of Absent. If the forward control parameter is derived from the video signal itself, it is independent In addition, outside the control loop of the compression encoder, the difficulty of the pre-processing operation ( ) Can be used to adjust This generally compresses the video signal And thus less coding artifacts. this is Pressure The most important parts of the video signal have been removed or modified to aid the compression process Because it is done.   Therefore, the preprocessing of the input digital signal can be adjusted to A method and apparatus for obtaining or more parameters are required.   According to the present invention, an incoming digital signal is generated to generate a signal for digital compression. A method of processing an incoming signal, comprising sampling an incoming signal at repetitive sample intervals of the signal. Adding the incoming signal to the storage means for storing the Deriving an absolute difference signal indicative of one or more parameters of the incoming signal. One or more, including the absolute difference between the floor and the sample adjacent in space or time Providing the above parameters and providing one or more field periods. Accumulating the difference signal and calculating the digital pressure of the incoming signal from the accumulated signal. Deriving a control signal indicating the presence of a component that limits the compression efficiency; and Processing the incoming signal to remove or limit components in the incoming signal. And a floor is provided.   Further, according to the present invention, the data input to generate a signal for digital compression is received. An apparatus for processing a digital signal, comprising the steps of: Storage means for storing the sample and one of the incoming signals from the stored samples. Or a first deriving means for deriving an absolute difference signal indicating more parameters. An accumulator that accumulates the difference signal over the or longer field period Means and accumulated trust Control signal indicating the presence of a component that limits the efficiency of digital compression of the incoming signal from the signal. A second deriving means for deriving, removing a component in the incoming signal according to the control signal; Consists of a processor for limiting, one or more parameters. The absolute difference between adjacent samples in space or time. An apparatus is provided.   If the digital signal is a video signal, the adjacent pixels in the vertical and temporal directions The absolute difference between the cell samples is the pixel sample of the incoming signal and one frame period later. Are the parameters of the incoming signal indicating the absolute difference between the corresponding samples. This is It is well correlated with the difficulty of digital compression of It can be used to provide control signals for the processor. But if possible It is preferable to use other parameters of the incoming signal in combination with the vertical and time parameters. New As will be explained later, the other parameters are purely vertical, purely time Direction, and also contains the absolute difference between pixel samples of the incoming signal in the horizontal direction.   Advantageously, the control signal is coupled to a number of components in the transmission chain. En When this is supplied to the coder, the compression approach is indicated by indicating the presence of an incoming critical image. Facts can be reduced. In a statistical multiplexing system, the control parameters Provides the statistical multiplexing control with the information needed for intelligent bandwidth allocation. You.   The invention will be described by way of example with reference to the accompanying drawings.   FIG. 1 is a digital video transmission according to one aspect of the present invention. It is a block diagram of a system.   FIG. 2 is a block diagram illustrating the use of control parameters in the system of FIG.   FIG. 3 is a diagram of a block circuit according to one embodiment of the present invention.   FIG. 4 is an explanatory diagram showing the function of the processing circuit included in the block circuit of FIG.   In the typical broadcast transmission system shown in FIG. 1, an input video signal 10 is pre-processed. It is sent to the encoder 12 via the control unit (preprocessor) 11. Pre-processing unit Can perform various functions such as downsampling and noise reduction. Faith The signal 10 is compressed in an encoder 12 and several compressed signals are And transmitted over a band-limited channel. The composite compressed signal 14 is a satellite 15 to the receiver. The transmission medium may be transmitted in any other suitable way, e.g. Cable or terrestrial transmission. The received signal 16 is converted by the demultiplexer 17 Each component signal is separated. Each received compressed signal is sent to the decoder 16 and output. A video signal 19 is generated.   FIG. 2 shows one embodiment of the present invention. In some cases, the input signal It is useful to analyze No. 20. This can be done as follows. Input signal No. 20 is sent to the preprocessing unit 21 and the analysis unit 22. The analysis unit 22 receives the input signal 20 Is measured and a corresponding control signal 28 is generated. The control signal is Sent to the preprocessor 21 to modify the incoming digital signal 20 or to encode -Send it to Da23, The criticality of the incoming digital signal 20 can be indicated. In some cases, The control signal can be sent to both the pre-processing unit and the encoder. Further control signals Sent to the statistical multiplexer control 24 for all input directories, including 20 and 25. Based on the criticality of the digital signal, it can help intelligent allocation of bandwidth. Next First, the composite bit stream 26 generated by the multiplexer 27 is shown in FIG. Is transmitted as shown in FIG. FIG. 3 shows an example of the analysis unit.   In FIG. 3, the first field storage unit 3 in series with the second field storage unit 32 is shown. An input terminal 30 is shown for receiving an incoming digital video signal applied to 1. . The incoming signal also includes a line store 33, a sample store 34, and four absolute It is added to the difference detectors 35, 36, 37, 38.   The absolute difference detection unit 35 is connected beyond the sample storage unit 34 and is adjacent in the horizontal direction. The absolute difference between successive pixel samples of the incoming digital video signal That is, each pixel sample of the video signal and the next pixel sample in the video signal. Detect the absolute difference of the sample. The difference signal obtained as a result is accu- Add to the muffler 39.   The absolute difference detection unit 36 is connected to the line storage unit 33 and is purely vertically adjacent. The absolute difference of each pixel sample, ie each pixel sample and one line period Detect absolute differences between subsequent pixel samples. Difference from detection unit 36 The signal is stored in the accumulator 40.   The absolute difference detection unit 37 is connected to the field storage unit 31, The absolute difference between each pixel sample in the vertical and temporal directions, i.e., each pixel The absolute difference between the pixel sample and the pixel sample after one field period . The difference signal from the detector 37 is stored in the accumulator 41.   The absolute difference detection unit 38 is connected to two field storage units, and stores each pixel sample. The absolute difference between the pull and the purely temporally adjacent pixel samples, ie Find the absolute value between each pixel sample and the pixel sample after one frame period. Put out. The difference signal from the detector 38 is stored in the accumulator 42.   The synchronization detecting section 43 receives the incoming digital video signal from the terminal 30. , A synchronous signal is detected and a timing signal is extracted. At the beginning, the accumulators 39, 40, 41 and 42 are reset, Turn off the input to each accumulator during horizontal blanking and delete the accumulator result At the end of the frame time, the data is latched in the analysis unit 44.   The analyzer 44 generates a control signal 47, which is the incoming video signal at the input 30. Is an index of the criticality of the coding. The coding criticality is determined under certain quality conditions, ie QP Is the number of bits generated for framing when x is fixed. The control signal 47 is transmitted to the other components of the transmission chain, namely the encoder or the statistics. To a dynamic multiplexer or to create a low-pass filter 45 in a diagonal field. Used to control movement. The filter 45 converts the incoming digital video signal The digital signal is filtered and output from an output terminal 46 to a digital compression encoder (not shown). Prepare to supply to The reason for using a diagonal low-pass filter is that MP This is because it is a diagonal frequency element that is difficult for the EG compression process. But the book The invention is not limited to a particular type of filter; Components known to be difficult to compress by choice of compression algorithm Is determined by   The signals stored in the accumulators 39, 40, 41 and 42 are represented by A, When referred to as B, C and D, the analyzer circuitry 44 provides a measure of image coding criticality. A control signal N which is calculated as a weighted sum by the following equation: . N = k ｛(W_AA)^Two+ (W_BB)^Two+ (W_CC)^Two+ (W_DD)^Two｝ Here, k is a constant determined by a coding algorithm, and W_A, W_B, W_C And W_DIs a weighting factor that sums to 1.   Experiments have shown that the values of each weighting factor are as follows.     W_A= 0.24, W_B= 0.35, W_C= 0.41, W_D= 0   The control signal N is an MPEG-2 coding process when QP is fixed at 7. It optimally correlates to the number of bits generated by the source. Correlation is bigger in video sequences Performed on a sample_DMay be a non-zero value. Already One way is to ignore the effect of the accumulated signal D and therefore to store one field. Is to save money.   FIG. 4 shows the effect of the control signal N when adjusting the bandwidth of the filter 45. You. Operating the system at different bit rates requires different control characteristics. In order to avoid this, a normalized value of the control signal N is used. From FIG. When the value of the signal N indicating that image criticality is low is low, that is, filtering (filtering) When there is no, it can be seen that the bandwidth of the filter is set to 1. Image As the field rises and coded artifacts begin to appear, the bandwidth Gradually decreases to a minimum value of about one quarter of₁To the value N_TwoRegular within range The probability of coding artifacts decreases with the rise of the coded signal N. This value N₁When N_TwoIs empirically obtained. Image quality is improved even with lower bandwidth This is because the bandwidth of the filter is the limiting factor.   The stored signal C was the best measure of the coding criticality of the incoming video signal, This signal can thus be used independently to generate the control signal N. Do you get it. However, the best result is to store the stored signal C in one of the stored signals A, B and D. Or more.   The storage and processing circuits shown and described with respect to the block circuit diagram of FIG. FIG. 3 shows a hardware embodiment of the present invention. The program microprocessor can be used to obtain the functions shown in the diagram. It is clear that you can.   The invention is applied to digital video signals, Or, a digital signal representing a series of images has been described. However, the present invention It is not limited to compression of digital video images. For example, it is apparent that the present invention can be applied to compression of a signal representing audio information. Further In addition, changing the number of components in the system without departing from the scope of the invention be able to.

[Procedure amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] July 22, 1998 (1998.7.22) [Contents of amendment] Description Method and apparatus for processing digital signals The present invention relates to a method and apparatus for processing an input digital signal to generate a signal for digital compression. Digital video compression systems typically perform many pre-processing functions first, which pre-condition the video signal and do not perform pre-processing for a given data rate. Try to get better images than usual. Examples of such operations are horizontal and downward sampling and noise reduction techniques. WO 95/15659 (D1) relates to the field of 3: 2 pulldown. The 3: 2 pulldown increases the frame rate of the movie sequence so that it can be displayed on a standard television in the United States. This increase is achieved by periodically repeating certain fields in the film sequence. From an encoder's point of view, this results in some coding inefficiency. First, the information is redundantly coded to repeat the fields (or frames). This problem can be substantially overcome by using the technique described on page 32-34 of D1. D1 describes the determination of how to code a given image or film using absolute differences. US Pat. No. 5,491,514 (D2) relates to a device for coding and / or decoding signals. D2 discloses measuring the mobility in the video signal so that the pre-filter (enhancement) circuit can be adjusted. This is done by calculating the variance or the sum of the differences. EP 0708564 (D3) discloses a method in which frames are delayed in an encoder, statistical data of each frame is generated, and the operation of the encoder is adjusted using the statistical data. It relates to the control of the encoder. EP 0444918 (D4) relates to controlling the quantization size in accordance with the prediction of the amount of code required to code the video sequence (column 6, line 7 to line 6). Column 7, line 24). The video signal is stored in the frame memory, and the code amount is estimated. The size of the quantization step and the bandwidth of the filter are adjusted to reach the target code volume. WO 9529550 (D5) relates to a device for determining the amount of calculation. The input video signal is filtered, subsampled, and sent to a variable length encoder. This is an alternative to measuring the coding "criticality" of the video signal. The quantization parameters generated by the compression encoder can be used as control parameters to control the amount of pre-processing applied to the input video signal to reduce coding artifacts. . However, if quantization parameters (QP) are used from the encoder to control the pre-processing operation, positive feedback (positive feedback) occurs and the system becomes unstable. In order to interrupt the feedback loop, the incoming video signal itself must be analyzed prior to compression and estimating the "criticality" of the resulting coding. When the forward control parameters are derived from the video signal itself, it can be used independently and outside the control loop of the compression encoder to adjust the difficulty of the preprocessing operation. Can be used. This generally makes the video signal easier to compress and therefore less coded artifacts. This is because the most important parts of the video signal have been removed or modified to aid the compression process. Therefore, there is a need for a method and apparatus for adjusting the pre-processing of an input digital signal to obtain one or more parameters prior to signal compression. According to the present invention, there is provided a method of processing an incoming digital signal in order to generate a signal for digital compression, the method comprising storing the incoming signal in storage means for storing samples of the incoming signal at repetitive sample intervals of the signal. Adding, deriving, from the stored samples, an absolute difference signal indicative of one or more parameters of the incoming signal, one or more including the absolute differences of spatially or temporally adjacent samples. Providing the above parameters, accumulating the difference signal over one or more field periods, and indicating from the accumulated signal the components that limit the efficiency of digital compression of the incoming signal. Deriving a control signal and processing the incoming signal to remove or limit components in the incoming signal in response to the control signal. Wherein the is provided. Further, according to the present invention, there is provided an apparatus for processing an incoming digital signal to generate a signal for digital compression, comprising storage means for storing samples of the incoming signal at repetitive sample intervals of the signal; First deriving means for deriving an absolute difference signal indicative of one or more parameters of the incoming signal from the samples obtained, and accumulator means for accumulating the difference signal over one or more field periods. Second deriving means for deriving, from the accumulated signal, a control signal indicating the presence of a component that limits the efficiency of digital compression of the incoming signal, and removing or limiting a component in the incoming signal according to the control signal. And one or more parameters comprising the absolute difference of spatially or temporally adjacent samples. Device is provided. If the digital signal is a video signal, the absolute difference between pixel samples adjacent in the vertical and temporal directions indicates the absolute difference between the pixel sample of the incoming signal and the corresponding sample one frame period later. These are signal parameters. This correlates well with the difficulty of digitally compressing the incoming signal and can itself be used to provide control signals for the preprocessor independently. Preferably, however, other parameters of the incoming signal are used in combination with the vertical and time parameters. As will be explained later, other parameters include the absolute difference between pixel samples of the incoming signal that are purely vertical, purely temporal, and horizontal. Claims 1. A method of processing an incoming digital signal to generate a signal for digital compression, the method comprising: applying the incoming signal to storage means for storing samples of the incoming signal at repetitive sample intervals of the signal; Deriving two or more absolute difference signals from the samples, wherein at least one difference signal is derived from spatially or temporally adjacent samples; and this difference signal over one or more field periods. And weighting the stored signal so that the weight of at least two of the stored signals is not 0. From the weighted signal, determine the presence of a component that limits the efficiency of digital compression of the incoming signal. Deriving a control signal to indicate or remove said component in the incoming signal in response to the control signal. The method of the steps has to process the incoming signal. 2. Providing an incoming digital signal as a video signal containing pixel samples, and providing the one or more parameters as an absolute difference between vertically and temporally adjacent pixel samples. 2. The method according to 1. 3. 3. The method of claim 2, further comprising providing the one or more parameters as absolute values between purely vertically adjacent pixel samples. 4. The method according to claim 2 or 3, further comprising the step of providing the one or more parameters as absolute values between purely temporally adjacent pixel samples. 5. The method of any of claims 2 to 4, further comprising the step of providing the one or more parameters as absolute values between horizontally adjacent pixel samples. 6. The method according to any of the preceding claims, further comprising the step of filtering the incoming signal through a low-pass filter whose bandwidth is controlled by the control signal. 7. The method according to any of the preceding claims, further comprising using a control signal as an aid for compression. 8. The method of any of claims 1 to 7, further comprising the step of coupling the control signal to a statistical multiplexing system. 9. Generating a control signal N from the equation N = k {(W _A A) ² + (W _B B) ² + (W _C C) ² + (W _D D) ² }, wherein: k is co - is a constant determined by the de _{algorithm, W a, W B, W} C, W D is the weighted factor that sum is 1, a, B, C, D is stored signal, wherein Item 9. The method according to any one of Items 1 to 8. 10. A device for processing an incoming digital signal to generate a signal for digital compression, comprising: storage means for storing samples of the incoming signal at repeated sample intervals of the signal; and two or more of the stored samples. First deriving means for deriving a further absolute difference signal, accumulator means for accumulating the difference signal over one or more field periods, and weighting at least two accumulated signals so that the weight is not zero. Weighting means for performing on the accumulated signal; second deriving means for deriving, from the accumulated signal, a control signal indicating the presence of a component limiting the efficiency of digital compression of the incoming signal; A processor for removing or limiting the component, wherein at least one of the two or more difference signals is spatial Others are absolute difference adjacent samples in the time direction device. 11. The apparatus of claim 10, wherein the incoming digital signal is a video signal including pixel samples, and wherein the one or more parameters include an absolute difference between vertically and temporally adjacent pixel samples. 12. The apparatus of claim 11, wherein the one or more parameters comprises absolute differences between purely vertically adjacent pixel samples. 13. Apparatus according to any of claims 11 or 12, wherein said one or more parameters comprises purely the absolute difference of temporally adjacent pixel samples. 14． 14. Apparatus according to any of claims 11 to 13, wherein the one or more parameters include the absolute difference between horizontally adjacent pixel samples. 15. Apparatus according to any of claims 10 to 14, wherein the processor comprises a low-pass filter whose bandwidth is controlled by a control signal. 16. 16. Apparatus according to any of claims 10 to 15, wherein the control signal is operatively connected to the encoder. 17． Apparatus according to any of claims 10 to 16, wherein the control signal is operatively connected to the statistical multiplexing device. 18. Second deriving means operates according to the equation _{N = k {(W A A} ) 2 + (W B B) 2 + (W C C) 2 + (W D D) 2}, in the formula, N represents the control a signal, k is co - is a constant determined by the de _{algorithm, W a, W B, W} C, W D is the weighted factor that sum is 1, a, B, C, D is stored signal Apparatus according to any of claims 10 to 17, wherein

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Claims (1)

[Claims] 1. A method of processing an incoming digital signal to generate a signal for digital compression, the method comprising: applying the incoming signal to storage means for storing samples of the incoming signal at repetitive sample intervals of the signal; Deriving, from the samples, an absolute difference signal indicative of one or more parameters of the incoming signal; and estimating said one or more parameters including the absolute difference of spatially or temporally adjacent samples. Providing, storing the difference signal over one or more field periods, and deriving from the stored signal a control signal indicative of the presence of a component that limits the efficiency of digital compression of the incoming signal. Processing the incoming signal to remove or limit said components in the incoming signal in response to a control signal. 2. Providing an incoming digital signal as a video signal containing pixel samples, and providing the one or more parameters as an absolute difference between vertically and temporally adjacent pixel samples. 2. The method according to 1. 3. 3. The method of claim 2, further comprising providing the one or more parameters as absolute values between purely vertically adjacent pixel samples. 4. The method according to claim 2 or 3, further comprising the step of providing the one or more parameters as absolute values between purely temporally adjacent pixel samples. 5. The method of any of claims 2 to 4, further comprising the step of providing the one or more parameters as absolute values between horizontally adjacent pixel samples. 6. The method according to any of the preceding claims, further comprising the step of filtering the incoming signal through a low-pass filter whose bandwidth is controlled by the control signal. 7. The method according to any of the preceding claims, further comprising using a control signal as an aid for compression. 8. The method of any of claims 1 to 7, further comprising the step of coupling the control signal to a statistical multiplexing system. 9. Generating a control signal N from the equation N = k {(W _A A) ² + (W _B B) ² + (W _C C) ² + (W _D D) ² }, wherein: k is co - is a constant determined by the de _{algorithm, W a, W B, W} C, W D is the weighted factor that sum is 1, a, B, C, D is stored signal, wherein Item 9. The method according to any one of Items 1 to 8. 10. An apparatus for processing an incoming digital signal to generate a signal for digital compression, comprising: storage means for storing samples of the incoming signal at repetitive sample intervals of the signal; and First deriving means for deriving an absolute difference signal indicative of one or more parameters; accumulator means for accumulating the difference signal over one or more field periods; Second deriving means for deriving a control signal indicating the presence of a component that limits the efficiency of digital compression of the signal; and a processor for removing or limiting the component in the incoming signal according to the control signal. An apparatus wherein said one or more parameters comprises the absolute difference of spatially or temporally adjacent samples. 11. The apparatus of claim 10, wherein the incoming digital signal is a video signal including pixel samples, and wherein the one or more parameters include an absolute difference between vertically and temporally adjacent pixel samples. 12. The apparatus of claim 11, wherein the one or more parameters comprises absolute differences between purely vertically adjacent pixel samples. 13. Apparatus according to any of claims 11 or 12, wherein said one or more parameters comprises purely the absolute difference of temporally adjacent pixel samples. 14． 14. Apparatus according to any of claims 11 to 13, wherein the one or more parameters include the absolute difference between horizontally adjacent pixel samples. 15. Apparatus according to any of claims 10 to 14, wherein the processor comprises a low-pass filter whose bandwidth is controlled by a control signal. 16. 16. Apparatus according to any of claims 10 to 15, wherein the control signal is operatively connected to the encoder. 17． Apparatus according to any of claims 10 to 16, wherein the control signal is operatively connected to the statistical multiplexing device. 18. Second deriving means operates according to the equation _{N = k {(W A A} ) 2 + (W B B) 2 + (W C C) 2 + (W D D) 2}, in the formula, N represents the control a signal, k is co - is a constant determined by the de _{algorithm, W a, W B, W} C, W D is the weighted factor that sum is 1, a, B, C, D is stored signal Apparatus according to any of claims 10 to 17, wherein